Measurement of thermal-mechanical noise in MEMS microstructures

Stievater, Todd H.; Rabinovich, William S.; Newman, H. S.; Mahon, Rita; Goetz, Peter G.; Ebel, J.; McGee, David J.

doi:10.1117/12.472753

Cited by 2 publications

(1 citation statement)

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“…The electrical noise characterization [12] measured the 1/f-noise and Johnson noise enabling the noise equivalent pressure (NEPr) to be calculated using the sensor measured sensitivity data. The thermal-mechanical noise level [13], [14] was also calculated. Johnson noise and 1/f-noise are related to the motion and scattering of the electronic carriers in the piezoresistors.…”

Section: Introductionmentioning

confidence: 99%

Flexible Conformal Micromachined Absolute Pressure Sensors

Ahmed

Chitteboyina

Butler

et al. 2015

J. Microelectromech. Syst.

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The fabrication and characterization of micromachined piezoresistive absolute pressure sensors in a flexible substrate is presented. A suspended aluminum oxide diaphragm containing nichrome (Ni-80%/Cr-20%) piezoresistive sensors backed by a vacuum cavity was utilized to form the sensor. The piezoresistors were placed in a half-Wheatstone bridge geometry to provide a linear response and thermal stability. The average value of the gauge factor of nichrome was measured to be 1.95. The average normalized Hooge coefficient K 1/ f was found to be 4.64 × 10 −11 for the nichrome piezoresistors. The pressure sensors displayed an average sensitivity of 1.25 nV/Pa and average value of noise equivalent pressure (NEPr) of 7.44 kPa in the bandwidth of 1-10 Hz in the 1/ f -noise limited regime. In the Johnson noise-limited regime, the NEPr was found to be 10 Pa in a 1-Hz bandwidth.[ 2014-0028]Index Terms-Absolute pressure sensor, flexible substrate, noise equivalent pressure.

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Section: Introductionmentioning

confidence: 99%